Exercise machine with stationary bicycle and inflatable seat

ABSTRACT

An exercise machine may include a frame with foot pedals mounted thereon and a seat having an inflatable bladder whereby the user may undertake a cardiovascular workout and a core workout of abdominal and back muscles.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. patent application Ser. No.14/744,286 filed Jun. 19, 2015, which is a continuation of U.S. patentapplication Ser. No. 13/132,178, filed Jun. 1, 2011, now U.S. Pat. No.9,079,067, which is a 371 National Phase of PCT Application Serial No.PCT/US2010/000797, filed Mar. 17, 2010, which claims priority to U.S.Provisional Patent Application Ser. No. 61/216,599, filed May 18, 2009;the entire disclosures of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION 1. Technical Field

The present invention relates generally to exercise machines. Moreparticularly, the exercise machine includes or is in the form of astationary bicycle which uses an inflatable seat to provide exercise ofthe core muscles of a person's trunk in combination with thecardiovascular exercise achieved primarily by pedaling the bicycle.

2. Background Information

Stationary bicycles are well known in the field of exercise machines.The primary focus of stationary bicycles is the exercise of the legs toprovide a cardiovascular workout. However, the stationary bicycle doesrelatively little to provide a workout of the core muscles or trunkmuscles of a person's stomach region and back region. Thus, it would beuseful in the art to provide a stationary bicycle which does providesuch a workout, especially for people who are interested in undertakinga more advanced exercise. The present invention primarily addresses thisconcern.

BRIEF SUMMARY OF THE INVENTION

In one aspect, an exercise machine may comprise a frame; a set of pedalsmovably mounted on the frame; a seat-receiving space defined by theframe rearward of the set of pedals; an inflatable seat within theseat-receiving space; and a seat back which extends upwardly of andadjacent the inflatable seat and is adapted for resting a user's backagainst while the user is seated on the inflatable seat.

In another aspect, an exercise machine may comprise a frame; a set ofpedals movably mounted on the frame; a seat-receiving space defined bythe frame rearward of the set of pedals; an inflatable seat within theseat-receiving space having an outer surface which has a bottom; and aseat support having an upwardly facing top surface and comprising a backsection which is rigidly secured to the frame and a front section whichis cantilevered upwardly and forward from the back section to a terminalfree front end; wherein the outer surface of the inflatable seat isseated on the top surface of the seat support so that a portion of theouter surface which extends forward and upward from the bottom of theouter surface is in contact with the top surface of the seat support;and the front section flexes downwardly in response to a downward forceon the inflatable seat.

In another aspect, an exercise machine may comprise a frame; a set ofpedals movably mounted on the frame; a seat-receiving space defined bythe frame rearward of the set of pedals; an inflatable seat within theseat-receiving space having an outer surface which has a bottom andwhich is convexly curved as viewed from the side of the inflatable seat;and a seat support rigidly secured to the frame and having an upwardlyfacing top surface which is concavely curved as viewed from the side ofthe inflatable seat; wherein the convexly curved outer surface is seatedon the concavely curved top surface so that a portion of the convexlycurved outer surface which extends forward and upward from the bottom ofthe convexly curved outer surface is in contact with the concavelycurved top surface.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

A preferred embodiment of the invention, illustrated of the best mode inwhich Applicant contemplates applying the principles, is set forth inthe following description and is shown in the drawings and isparticularly and distinctly pointed out and set forth in the appendedclaims.

FIG. 1 is a perspective view of a first embodiment of the stationarybicycle of the present invention.

FIG. 2 is similar to FIG. 1 and shows the inflatable seat removed fromthe frame with portions cut away and shown in section.

FIG. 3 is a sectional view of a modified inflatable seat and a modifiedmounting structure for mounting the seat thereon.

FIG. 4 is a sectional view similar to FIG. 3 showing another modifiedinflatable seat and associated modified mounting structure for the seat.

FIG. 5 is a side elevational view of the stationary bicycle withportions cut away and portions in section to show a pneumatic system andseat height sensor with the inflatable seat in the decompressed restingposition.

FIG. 6 is similar to FIG. 5 and shows the user of the machine seated onthe inflatable seat which is compressed to a certain degree to show oneof many possible compressed positions.

FIG. 7 is a left side elevational view of a second embodiment of thestationary bicycle of the present invention.

FIG. 8 is a right side elevational view of the second embodiment with aportion of the inflatable seat cut away and shown in section.

FIG. 9 is a rear end elevational view of the second embodiment.

FIG. 9A is a sectional view taken on line 9A-9A of FIG. 7.

FIG. 9B is a sectional view taken on line 9B-9B of FIG. 12.

FIG. 9C is a sectional view taken on line 9C-9C of FIG. 8.

FIG. 10 is a front end elevational view of the second embodiment.

FIG. 11 is a top plan view of the second embodiment.

FIG. 12 is a bottom plan view of the second embodiment.

Similar numbers refer to similar parts throughout the drawings.

DETAILED DESCRIPTION OF THE INVENTION

A first embodiment of the stationary exercise bicycle or bike of thepresent invention is shown generally at 10 in FIGS. 1 and 2; and asecond embodiment of the stationary exercise bicycle of the presentinvention is shown generally at 100 in FIGS. 7-12. In accordance withthe invention, bike 10 includes an inflatable seat 12. Although seat 12has a spherical shape, it may be configured in a variety of shapes. FIG.3 shows an alternate inflatable seat 12A which is substantiallyspherical and FIG. 4 shows inflatable seat 12B which is substantiallyhemispherical. Bike 10 includes a rigid frame 14 typically made of ametal such as steel or the like. Frame 14 has a front 16 and a back 18defining therebetween a longitudinal direction of the frame and bike.Frame 14 has left and right sides 20 and 22 defining therebetween anaxial direction of the frame and the bike. In the exemplary embodiment,frame 14 is configured as a free standing frame which is typicallyseated on a floor F (FIGS. 3-6) although it may be secured otherwise.

Frame 14 includes a rigid tubular axially elongated front floor orstability bar 24 and a rigid tubular axially elongated rear floor orstability bar 26 which is substantially parallel to bar 24. Each of bars24 and 26 is typically straight and horizontal and has left and rightend caps 25 mounted thereon which are seated on floor F and typicallyformed of a material which resists sliding along the floor and issufficiently soft to minimize or eliminate scratching the floor. Frame14 further includes a bottom longitudinal frame member 28 which islongitudinally elongated and extends horizontally between and is rigidlysecured to bars 24 and 26. Each of bars 24 and 26 have respective leftand right segments which extend axially outwardly in opposite directionsfrom their connection with frame member 28. Bars 24 and 26 thus providesuitable stability to bike 10 when seated on the floor. Bars 24 and 26and frame 28 are adjacent floor F when exercise machine 10 is seatedthereon.

Frame 14 further includes a rigid front elevated support 30 which isrigidly secured to and extends upwardly from the front of frame member28 and then rearwardly to a rear end which supports various componentsas noted further below. Frame 14 also includes a rigid tubular rear seatback support 32 which is in the form of an upright which is rigidlysecured to the rear end of frame member 28 and extends upwardly from therear member 28 and a rigid connection with rear bar 26. Longitudinalframe member 28 includes a rigid tubular straight rear longitudinalframe member 33 which is substantially horizontal and forms an L-shapedconfiguration in combination with support 32 via an arcuate tubularsegment 35. Frame 14 further includes rigid tubular left and right arms34A and 34B which are secured to upright support 32 and extendrespectively axially outwardly therefrom, and forward and downwardly toframe member 33. In the exemplary embodiment, left and right arms 34Aand 34B are mirror images of one another and thus are bilaterallysymmetrical about a vertical central longitudinally extending plane P1passing through the center of exercise machine 10 midway between leftand right sides 20 and 22.

Each arm 34 in the exemplary embodiment is formed of a single tube whichthus extends from a first or rear end 37 attached at a rigid connection39 to support 32 to a second or forward end 41 attached at a rigidconnection 43 to frame member 33. Rear end 37 and connection 39 arerearward and higher than forward end 41 and connection 43. FIG. 5illustrates a line L1 extending through the respective centers of ends37 and 39 or connections 39 and 43 whereby line L1 and a horizontalplane such as floor F define therebetween an obtuse angle K whichillustrates in part that line L1 angles upwardly and rearwardly. In theexemplary embodiment, angle K is typically in the range of about 120,125, or 130 degrees to about 140, 145, or 150 degrees although this mayvary. Left and right rigid side-grip handles 36A and 36B arerespectively secured to left and right arms 34A and 34B and projectoutwardly therefrom in cantilever fashion. Handles 36 typically includegrips formed of a resilient compressible material such as a foam,rubber, or elastomer. These grips of the handles may have built-in heartrate or pulse sensors.

Frame 14 further includes a rigid ball support in the form of a flatcircular plate or disc 38 which is substantially horizontal and securedto the top of frame member 33 adjacent the intersection with arms 34.Ball 12 is seated atop plate 38 and adjacent the back or rear end 18 ofthe frame. Although plate 38 provides a rigid support for ball 12, asupport may also be configured which allows for some degree of upwardand downward flexibility. For example, a plate or arms may be configuredwith a concavely curved upwardly facing surface of a matingconfiguration with the spherical outer surface of ball 12 such that theplate or arms are cantilevered to extend upwardly to free terminal endswhich can flex downwardly or otherwise in response to downward movementof ball 12 such as when a user applies force by sitting on top of theball. These cantilevered arms would likewise flex upwardly or otherwisewhen the downward force or weight is removed or reduced. Such arms couldbe formed of a relatively thin plate of metal such as steel or othermaterial of suitable thickness to allow for such flexibility, and mayalso have various types of cushions positioned thereon between the metalof the arms and the outer surface of the inflated seat.

In the exemplary embodiment, no glue, adhesive, or other fasteningdevices are used to secure ball 12 to frame 14. Thus, ball 12 may bemoved from the mounted position shown in FIG. 1 to the dismounted orremoved position shown in FIG. 2 separate from the frame by a simplemanual lifting force applied to the ball or seat. However, glue,adhesives, or other fasteners may be used to secure ball 12 to frame 14.For instance, hooks, closed loops or links of a chain, or tethers,cords, or the like may extend from ball 12 to frame 14 in order tosecure the ball to the frame. A seat back 40 is secured to support 32,typically including a relatively rigid rear portion attached to thesupport and a padded front section having a forward facing front surfaceagainst which the user leans during operation. Seat back 40 may besecured so that it is stationary relative to the frame, or may bemovably mounted on the frame to, for example, tilt forward andrearwardly. In addition, seat back 40 may be vertically adjustable andlongitudinally adjustable if desired.

Frame 14 includes a front section 42 and a rear section 44 which may beremovably connected to one another and in the exemplary embodiment areselectively secured to one another by a length adjustment mechanism 46.Mechanism 46 is configured to allow for the adjustment of the length offrame 14 and the length between the seat and pedals, as indicated atarrow A in FIG. 2. The portion of frame member 28 which is within frontsection 42 includes a rear section in the form of a straight horizontalrigid rear member in the form of a tube 48 which splits at its front endinto left and right rigid lower tubular forks 50A and 50B which areconnected adjacent their front ends to front floor bar 24 and elevatedsupport 30. A series of longitudinally spaced holes 52 are formed inrear tube 48 as well as in the front portion of frame member 33 suchthat the holes of each of these members may be aligned with one anotherto receive therethrough a securing peg 54 to secure the front and rearsections 42 and 44 to one another at a selected length of frame 14. Inthe exemplary embodiment, the front end of frame member 33 is slidinglyor telescopically received within the hollow interior of rear tube 48.Although the use of holes 52 and peg 54 provides a simple securingmechanism for the length adjustment assembly, other suitable securingmechanisms known in the art may also be used. Elevated support 30includes left and right rigid tubular upper forks 56A and 56B in theexemplary embodiment which are respectively secured to left and rightlower forks 50A and 50B and extend upwardly and rearwardly therefrom.

A rigid flywheel housing 58 is secured to frame 14 generally adjacentfront 16. In the exemplary embodiment, housing 58 is seated atop andsecured to forks 50 and secured to the forward portions of upper forks56. A set of left and right pedals 60A and 60B is rotatably mounted viaa rigid crank or axle 62 about a horizontal axially extending axis B ofaxle 62. Crank 62 extends outwardly to the left and right from housing58 with respective pedal arms 64A and 64B extending transversely andtypically roughly perpendicularly to the crank 62. Left pedal 60A isrotatably mounted at the outer end of pedal arm 64A about a horizontalaxially extending axis C of a left pedal axle such that axis C isparallel to and offset from axis B. Likewise, right pedal 60B isrotatably mounted at the end of pedal arm 64B about another horizontalaxis D of a right pedal axle such that axis D is parallel to axes B andC and offset therefrom. The pedal axles of pedals 60A and 60B thusoscillate during operation along respective circular paths concentricabout axis B while each pedal rotates about its respective pedal axle.Left and right crank-receiving holes 66A (FIGS. 1, 2) and 66B (FIGS. 5,6) are formed respectively through the left and right sides of housing58 for receiving therethrough respective portions of crank 62.

Rigid handle bars 68 are secured to the rear elevated free end of thecantilevered elevated support 30. Handle bars 68 include left and rightsegments with left and right front-grip handles 70A and 70B respectivelysecured to the terminal ends thereof. Handles 70 typically include gripssimilar to the grips of handles 36, and thus are formed of likematerials and may include heart rate or pulse sensors. It is noted thathandle bars 68 and/or handles 70 may be mounted in a variety of ways inorder to allow them to move between various positions. For example,handle bars 68 may be pivotably mounted to allow handles 70 to movebetween various raised and lowered positions and secured at thesevarious positions if desired. In addition, handle bars 68 and/or handles70 may be adjustable in the axial or longitudinal directions in order toposition the handles and secure them in accordance with the user'sdesire. Also secured to the free end of support 30 is a combinationdisplay and control unit 72 which typically includes a liquid crystaldisplay (LCD) and various controls used in the operation of bike 10. Thevarious controls are typically electrically operated and may utilize,for instance, various buttons, heat sensitive pads or pressure sensitivepads which can be manually operated. A variety of display functions maybe displayed on the LCD of unit 72. For instance, these displays mayinclude RPMs or revolutions per minute of the pedals during rotation,the amount of time that the bike has been operated by the user, thesimulated speed at which the user would be traveling on a real bicycle,the simulated distance that would be traveled on a wheeled bicycle, thecalories burned during the workout, the pulse or heart rate of the userduring training, the current room temperature in which the bike isoperated, a calendar showing the day, month and year, a clock indicatingthe current hour and minute and so forth. The display may include a scanoption which runs between various display functions to allow the user totrack various monitors and/or training programs. The display may alsoinclude a video screen to allow the user to watch videos, television,and/or speakers to assisting the same or listen to music and so forth.The display is in electrical communication with built-in heart rate orpulse sensors in the grips or handles 36 and 70.

Referring primarily to FIG. 2, arcuate left and right arms 34A and 34Bof the frame include respective left and right rear segments 74A and 74Bwhich extend respectively axially outwardly substantially horizontallyfrom upright 32, respective intermediate segments 76A and 76B whichextend respectively forward from rear segments 74A and 74B, and frontsegments 78A and 78B which extend respectively downwardly from the frontof intermediate segments 76A and 76B. Front segments 78A and 78Badjacent their lower ends extend axially inwardly toward their rigidconnection with frame member 33. More particularly, left and right rearsegments 74A and 74B extend axially outwardly along a generally straightline from upright 32 for a short distance and then curve forward andslightly upwardly to transition respectively into left and rightintermediate segments 76A and 76B, which curve forward and downwardly totransition into left and right front segments 78A and 78B. As viewedfrom above, the axial outer ends of rear segments 74A and 74B and therear portions of intermediate segments 76A and 76B curve so that theirinner surfaces 85 curve concavely and face generally forward and axiallyinward toward one another and plane P1 while their outer surfaces 87curve convexly and face generally rearwardly and axially outward awayfrom one another and plane P1. As viewed from the side, the bottomdownwardly facing surfaces 89 of intermediate segments 76A and 76B curveconcavely, while their top upwardly facing surfaces 91 curve convexly.As viewed from the side, the rearwardly facing back surfaces 93 of frontsegments 78A and 78B curve concavely while their front forward facingsurfaces 95 curve convexly. The lower ends of front segments 78A and 78Bcurve rearwardly to their respective connections 43 with frame member33. As viewed from the front or from the side, the top upwardly facingsurfaces 97 of the lower portions of front segments 78A and 78B adjacentthe connection with frame member 33 curve concavely while their bottomdownward facing surfaces 99 curve convexly.

Frame 14 adjacent rear end 18 defines a ball receiving space 75 having atop entrance opening 77, a front entrance opening 79, a left rearentrance opening 81 and a right rear entrance opening 83. Ball-receivingor seat-receiving space 75 is generally defined between arms 34A and34B, forward of upright 32 and above ball support 38. In the exemplaryembodiment, the top surface of ball support 38 defines the bottom ofspace 75, the front of upright 32 defines the back of space 75, andportions of intermediate segments 76 and/or front segments 78 of arms 34typically define the left and right sides of space 75. Top entranceopening 77 is defined between intermediate segments 76A and 76B whilefront entrance opening 79 is defined between front segments 78A and 78B.Left rear entrance opening 81 is defined generally between left arm 34A,upright 32, ball support 38 and the rear portion of frame member 33extending rearwardly from ball support 38. Similarly, right rearentrance opening 83 is defined generally between right arm 34B, upright32, ball support 38 and the rear portion of frame member 33 extendingrearwardly from support 38. In the exemplary embodiment, each of theentrance openings 77, 79, 81, and 83 is completely or substantially freeof any components extending between the various structures which definesaid entrance openings. In the exemplary embodiment, machine 10 is freeof or substantially free of components extending into space 75 otherthan inflated seat 12.

As shown in FIG. 2, inflatable seat 12 is formed of a substantiallyspherical bladder or wall 80 having a substantially spherical outersurface 82 and a substantially spherical inner surface 84 definingtherewithin a spherical interior chamber 86 when seat 12 is inflated andin a state of rest in which it is substantially not compressed otherthan by its own weight when seated on a surface. Bladder or wall 80 istypically formed of a rubber or elastomer which is flexible andstretchable while also being thick enough to support a user seatedthereon during the operation of bike 10. FIG. 2 also shows that outersurface 82 defines an outer diameter d which in the inflated restingstate is usually within a range of about 50 or 55 centimeters to about60 or 65 centimeters and more broadly within a range of about 35, 40, or45 centimeters to about 65, 70, or 75 centimeters.

When inflated seat 12 is mounted at rest on frame 14 as shown in FIGS. 1and 5, the bottom of outer surface 82 is seated on the horizontal topsurface of plate 38, while a rearward portion of the outer surface aboutmidway between the top and bottom of sphere 12 is typically closelyadjacent or abutting the front of seat support 32, and left and rightlower portions of the outer surface 82 in the forward half of thespherical seat 12 are closely adjacent or abutting the lower portions offront segments 78A and 78B. Typically, outer surface 82 has essentiallyonly a four-point contact with frame 14 at the locations noted above.Typically, intermediate segments 76A and 76B are spaced outwardly fromseat 12 and are thus not in contact with outer surface 82 of seat 12 atrest or when compressed when a user is seated thereon. Also typically,the above noted places of contact or interface between the outer surfaceof the sphere and the various surfaces of frame 14 are the only placesof contact between the ball and frame when the inflated ball is at restwhereby the remainder of outer surface 82 is out of contact with frame14. The portions of the frame which extend upwardly and contact theouter surface of seat 12 substantially prevent it from rolling atopplate 38. Seat 12 is also substantially non-rotatably mounted withinspace 75 due to frictional engagement (or securing devices if used)between seat 12 and frame 14. In its operational configuration, interiorchamber 86 is filled with a gas, which is most typically air. Thus,bladder or wall 80 is formed of a material which is impermeable to airor any other gas used therein. Seat 12 may or may not include an airinlet with a valve in order to allow the bladder to be inflated ordeflated.

When sphere 12 is inflated and in its resting state, frame 14 isconfigured to receive seat 12 within receiving space 75 through topentrance opening 77 and typically through a portion of front entranceopening 79, which together form an entrance opening which extendsgenerally upwardly and forward along intermediate segments 76 and frontsegments 78. Seat 12 is thus inserted downwardly either substantiallyvertically or downwardly and rearwardly through entrance opening 77 anda portion of opening 79 until it is seated atop ball support 38. Thisdownward or downward and rearward insertion of the sphere into space 75may or may not involve compression of the inflated seat against certainportions of arms 34. If such compression does occur, it is typically dueto a sliding engagement between the outer surface of the sphere and thelower portions of front segments 78 and/or support 32.

Once seat 12 is properly positioned within space 75, the lower portionsof front segments 78 may abut the outer surface of the sphere in itsresting state. The lower portions of front segments 78 will generallyprevent the ball from rolling forward out of space 75 through frontentrance opening 79. Although the ball might be forced horizontallyforward out of space 75 through front entrance opening 79, this wouldtypically require a substantial amount of force in order to providesufficient compression of the ball against and between segments 78A and78B to move through entrance opening 79. Generally, left and right rearentrance openings 81 and 83 are configured so that at least onedimension of the respective entrance opening is sufficiently less thanthe diameter of the inflated ball in order to prevent it from movingthrough the respective entrance opening during use of machine 10. Wheninflated ball seat 12 is positioned at a state of rest in receivingspace 75, side grip handles 36 are at a height which is about the sameas the top of the ball although they may be slightly higher or lower,while intermediate segments 76 are at a height which is also similar tothe height of the top of the ball although typically somewhat below thisheight. Handles 36 and intermediate segments 76 are typicallysubstantially above the height of the midway point between the top andbottom of the ball, (the center X of the ball) and typically at least ¾of the height of the ball. The forward most point of each front segment78 is typically spaced longitudinally forward from the seat supportabout the same distance as the front most portion of ball 12 andsomewhat rearward thereof in the exemplary embodiment although it may beforward thereof as well. As previously noted, FIGS. 3 and 4 showmodified versions of the inflatable seat. Inflatable seat 12A shown inFIG. 3 is substantially spherical although the bladder or wall 80A ismodified somewhat relative to that of wall 80 of seat 12. Bladder 80Aincludes a substantially spherical wall portion 88 and a recessed wallportion 90 which is secured to the bottom area of wall portion 88 andextends upwardly and inwardly therefrom. Recessed wall portion 90includes an annular side wall 92 which is typically either cylindricalor frustoconical in shape although other shapes may be used, and a topwall 94 secured to the top of annular side wall 92. Side wall 92 and topwall 94 define therewithin a bottom recess 96 having a bottom entranceopening 98 which communicates with outer surface 82 of spherical wallportion 88. Recessed wall portion 90 thus projects inwardly intointerior chamber 86 such that recess 96 is circumscribed or entirelysurrounded by the bottom portion of interior chamber 86 extendingradially outwardly from annular side wall 92 relative to a vertical axispassing through the center of recess 96. The outer surface 82 of bladder80A also has a diameter which is within the range as noted above withregard to bladder 80.

Frame 14 is altered in accordance with the use of inflatable seat 12A.More particularly, frame 14 includes an insert or projection 100 whichis rigidly secured to and extends upwardly from plate 38 and has anouter surface which is of a mating configuration with the surface ofrecessed wall portion 90 defining recess 96. Insert 100 thus includes anannular side wall 102 which is typically either cylindrical orfrustoconical in shape although other shapes may be suitable. Insert 100further includes a top wall 104 secured to the top annular side wall102. Insert 100 is essentially a post which extends upwardly and may beformed as a solid structure as well. When insert 100 is received inrecess 96, it is thus circumscribed or completely surrounded by sidewall 92 and the lower portion of interior chamber 86 extending radiallyoutwardly from side wall 92. The use of the recess 96 and insert 100therein thus provides a different way of mounting an inflatable seat onthe frame to substantially prevent it from rolling thereon. During useof seat 12A, recessed wall portion 90 typically remains substantiallyfixed or stationary while on the substantially spherical portion 88 isflexibly movable relative thereto during compression and decompressionas the user sits on and moves about on seat 12A. The insert 100 andrecess 96 may be configured such that seat 12A may simply be lifted offof insert 100 inasmuch as there may be no more than a frictionalengagement between the recessed wall portion 90 and insert 100 orperhaps a stretch fit in which recessed wall portion 90 may be requiredto stretch in order to fit over and be removed from insert 100. A glue,adhesive, or other fastener may also be used to help secure the outersurface of insert 100 to recessed wall portion 90.

As noted above, alternate inflatable seat 12B and an alternate mountingstructure are illustrated in FIG. 4. Seat 12B is substantiallyhemispherical in shape and includes a bladder or wall 80B having asubstantially hemispherical wall portion 106 and a substantially flatcircular bottom wall portion 108 secured to the bottom thereof in orderto define a substantially hemispherical interior chamber 86. Frame 14 ismodified to include an upright or support 110 which is rigidly securedto and extends upwardly from frame member 33 with a substantially flatcircular horizontal plate or disc 112 rigidly secured to the topthereof. Bottom wall portion 108 during operation thus remainssubstantially fixed or stationary while the hemispherical wall portion106 is flexibly and stretchably movable in response to the movements ofthe user while seated thereon. The flat bottom surface of bottom wallportion 108 is thus secured to the flat top surface of plate 112,typically with glue or some form of adhesive. Other known securingmechanisms such as Velcro® or the like may also be used. Outer surface82 of bladder 80B adjacent bottom wall portion 108 defines an outerdiameter as measured horizontally which is typically on the order ofabout 40 centimeters, usually within a range of 30 to 35 centimeters to45 or 50 centimeters and more broadly within a range of about 25centimeters to about 55 or 60 centimeters. The diameter of bottom wallportion 108 thus also falls within these ranges.

Referring now to FIG. 5, housing 58 includes left and right verticalpanels 114A and 114B (left panel 114A shown in FIG. 1). Housing 58further includes a perimeter wall 116 which is connected to therespective outer perimeters of vertical panels 114 whereby panels 114and perimeter wall 116 define therewithin an interior chamber 117 ofhousing 58. A generally flat and vertically oriented flywheel 118 isdisposed within interior chamber 117 with crank 62 rigidly secured atits center and extending outwardly therefrom to the left and right. Moreparticularly, holes 66A and 66B are formed respectively in left andright vertical panels 114A and 114B such that crank 62 extends axiallyoutwardly from flywheel 118 therethrough. A drive sprocket or pulley 119is secured to one side of flywheel 118 with its outer perimeterconcentric about axis B. A resistance mechanism 120 is provided withininterior chamber 117 in order to allow the user to control the amount ofresistance on flywheel 118 and thus to the pedaling motion of the user.A variety of resistance mechanisms may be used, such as a flexibleresistance belt which wraps around the outer perimeter of flywheel 118which may be tightened or loosened to adjust the resistance, a rigidbrake which may likewise be forced against flywheel 118 to a greater orlesser degree in order to adjust the resistance, or a magneticresistance mechanism (which eliminates friction via components otherwiseapplied against the flywheel during rotation). In addition, anadjustable air resistance system may be provided for example by amomentum washboard flywheel or a fan wheel.

An air compressor 122 is also disposed within interior chamber 117 witha driven sprocket or pulley 124 rotatably mounted on a drive shaft ofcompressor 122. A flexible drive chain or belt 126 which forms a closedloop wraps around drive pulley 119 and driven pulley 124 such that therotational movement of drive pulley 119 causes belt 126 to move in arevolving pattern to drive driven pulley 124 in order to power aircompressor 122 to produce compressed or pressurized air. An electroniccontrol unit 128 having a microprocessor is also typically disposed ininterior chamber 117. Air compressor 122 is in fluid communication withinterior chamber 86 of seat 12 via an air conduit 130 having a first end132 secured to compressor 122 and a second opposed end 134 connected tothe bottom of bladder 80. An air valve 136 is provided along air conduit130 for controlling the flow of air through conduit 130. Control unit128 is in electrical communication with air valve 136 via an electricalconductor or wire 138. A height sensor 140 is mounted adjacent thebottom of bladder 80 within interior chamber 86 of seat 12. Control unit128 is in electrical communication with sensor 140 via an electricalconductor or wire 142.

FIG. 5 shows that plate 38A is modified with a hole 144 through whichconduit 130 and wire 142 pass. In the exemplary embodiment, conduit 130and wire 142 extend primarily through the hollow tube formed by portionsof the front and rear sections of frame member 28. Bladder 80 mayinclude a thickened mounting portion 146 adjacent its bottom in order toprovide sufficient support to sensor 140 and conduit 130 adjacent it'ssecond end 134. As shown in FIG. 5, outer surface 82 of bladder 80includes an upwardly facing seating surface 148 at the top of theinflatable seat which is at a height H1 relative to frame 14 and floor Fwhen the inflatable seat 12 is in its resting state or position. Areference point P is provided on inner surface 84 which in the exemplaryembodiment is directly below seating surface 148 although this may vary.

The operation of bike 10 is now described with primary reference toFIGS. 5 and 6. As illustrated in FIG. 5, sensor 140 is used to measurethe vertical distance between sensor 140 and reference point P such asby emitting a suitably low powered laser beam LB which is directed atreference point P and which is typically reflected back and sensed bysensor 140 in order to provide a signal to the microprocessor of controlunit 128 to establish this vertical distance and thus height H1. Whenthe user or person 150 sits down on seating surface 148 as illustratedin FIG. 6, the bladder 80 is flexibly and stretchably deformed andcompressed by the weight of the user such that the upper portion ofbladder 80 including seating surface 148 moves downwardly as indicatedat arrow E to a lower height H2. Reference point P accordingly movesdownwardly such that the vertical distance from sensor 140 and point Pis reduced relative to the resting state shown in FIG. 5. Laser beam LBis thus reflected a shorter distance such that it is sensed to form asignal which is translated by the microprocessor in order to determinethe vertical distance and thus height H2. Obviously, the differencebetween height H1 and height H2, and thus the degree to which seatingsurface 148 moves downwardly from height H1, depends upon the weight ofthe person 150 seated on seat 12. Inasmuch as height H2 may thus behigher or lower than the most preferred or desired height for operationof bike 10, the pneumatic system may thus be controlled by control unit128 in order to either further inflate or deflate inflatable seat 12(adjust the internal pressure of bladder 80) in order to adjust theheight of seating surface 148 to the desired position. Moreparticularly, if height H2 is determined by unit 128 is determined to betoo high, control unit 128 is able to control valve 136 in order toallow bladder 80 to be suitably deflated or reduce its internal pressurein order to lower the seating surface 148 to the appropriate height. Ifthe height of seating surface 148 is determined to be too low, controlunit 128 is likewise able to control valve 136 in order to allowcompressed air from compressor 122 to further inflate seat 12 orincrease the internal pressure of bladder 80, as indicated by the linesG, which illustrate air or another gas moving into interior chamber 86.In the exemplary embodiment, air compressor 122 is powered by user 150as the user pedals or applies the appropriate rotational force to thepedals in order to rotate the pedals, flywheel 118, and drive pulley 119in order to drive the driven pulley 124 via belt 126 to operate aircompressor 122.

It is noted that the movement of the inflated seat 12 from its restingstate in FIG. 5 to its compressed state in FIG. 6 in response to thedownward force of the user seated thereon not only obviously alters theshape of the seat, but also increases the surface area of contactbetween outer surface 82 and frame 14. More particularly, FIG. 5illustrates that the outer surface at the bottom of the sphere 12contacts only a portion of the top surface of plate 38A in the restingstate whereas the surface area of contact between outer surface 82 andthe top surface of plate 38A in the compressed position of FIG. 6 showsthat the entire top surface of plate 38A is in contact with outersurface 82. In addition, FIG. 5 shows a relatively small contact areabetween the front of upright 32 and the rear portion of outer surface 82in the resting state of FIG. 5 while FIG. 6 shows a substantiallygreater contact surface area between outer surface 82 and the front ofupright 32 in the compressed state of the inflated seat. Similarly, thecontact surface area between outer surface 82 and the lower portion offront segments 78 increases from the resting state of FIG. 5 to thecompressed state of FIG. 6.

As illustrated in FIG. 6, the user 150 typically will rest his or herback against seat back 40 while seated on inflatable seat 12 andpedaling the stationary bike. The user may hold on to handles 70 asillustrated in solid lines, or handles 36 as illustrated in dashedlines. Pulse or heart rate sensors in handles 70 or 36 are configured tosense the user's pulse and send corresponding signals to control unit128 in order to display the pulse or heart rate of the user whileexercising on bike 10. The user seeking a more challenging workout maychoose not to hold on to any handles at all and furthermore may not leanagainst back rest 40. Regardless of the alternate position for thehands, bike 10 provides a combination of a cardiovascular workoutprimarily via the pedaling of the bike along with a core workoutprimarily for the abdominal and back muscles primarily via inflatableseat 12. More particularly, the nature of inflatable seat 12 means thatseating surface 148 does not remain stationary while the user's feet areapplying force to pedals 60 in order to pedal bike 10. This movement ofseating surface 148 is primarily due to the inflatable aspect of seat 12along with the flexible and stretchable material of which bladder 80 isformed whereby seating surface 148 is able to move in any directionrelative to frame 14. Thus, user 150 is faced with the additionalchallenge of balancing on seat 12 while simultaneously pedaling thebike. As a result, user 150 is forced to use abdominal muscles and backmuscles to a substantially larger degree than would occur with a simplepedaling workout on a stationary seat.

Bike 200 is now described with reference to FIGS. 7-12. Bike 200 isparticularly configured to use the spherical seat 12 which was describedin greater detail above although modifications may be made to use otherseats such as seat 12A and seat 12B also described previously. Bike 200includes a rigid frame 214 typically made of a metal such as steel orthe like. Frame 214 has a front 16 and a back 18 defining therebetween alongitudinal direction of the frame and bike. Frame 214 has left andright sides 20 and 22 defining therebetween an axial direction of theframe and the bike. In the exemplary embodiment, frame 214 is configuredas a free standing frame which is typically seated on a floor F (FIGS.7-9) although it may be secured otherwise.

Frame 214 includes a rigid tubular axially elongated front floor orstability bar 24 and a rigid tubular axially elongated rear floor orstability bar 26 which is substantially parallel to bar 24. Each of bars24 and 26 is typically straight and horizontal and has left and rightfeet in the form of end caps 25 mounted thereon so that the lowerportions of feet 25 extend respectively downwardly from bars 24 and 26and are seated on or contact floor F. Feet 25 are typically formed of amaterial which resists sliding along the floor and is sufficiently softto minimize or eliminate scratching the floor, for example, rubber, anelastomer, plastic, fabric or the like. Frame 214 further includes abottom longitudinal frame member 228 which is longitudinally elongatedand extends horizontally between and is rigidly secured to bars 24 and26. Each of bars 24 and 26 have respective left and right segments whichextend axially outwardly in opposite directions from their connectionwith frame member 228. Bars 24 and 26 thus provide suitable stability tobike 200 when seated on the floor. Bars 24 and 26 and frame 228 areadjacent floor F when exercise machine 200 is seated thereon.

Frame 214 further includes a rigid front elevated support 230 which isrigidly secured to and extends upwardly from the front of frame member228 and then rearwardly to a rear end. Frame 214 further includes arigid crank support assembly which supports various components as notedfurther below. The crank assembly includes a crank support bar 201 whichextends upwardly and rearwardly and an additional crank support bar 202which extends rearwardly and downwardly to a rigid connection withsupport bar 201. Frame 214 also includes a rigid rear seat back support232 which is rigidly secured to the rear section of frame member 228 andextends upwardly therefrom. Longitudinal frame member 228 includes arigid tubular straight horizontal rear longitudinal frame member 233which is substantially horizontal and has front and rear ends 203 and204 defining therebetween a longitudinal interior chamber 205. Rear end204 is rigidly secured to the front of rear bar 26. Frame 214 furtherincludes rigid tubular left and right arms 234A and 234B which aresecured to upright support 232 and extend respectively axially outwardlytherefrom, and forward and downwardly to frame member 233. In theexemplary embodiment, left and right arms 234A and 234B are mirrorimages of one another and thus are bilaterally symmetrical about avertical central longitudinally extending plane P1 (FIGS. 9-12) passingthrough the center of exercise machine 200 midway between left and rightsides 20 and 22.

Rear seat back support 232 includes left and right rigid support members235A and 235B each of which in the exemplary embodiment is formed of asingle elongated tube which is bent to form a front lower horizontallongitudinal segment 245, an arcuate back segment 247 which curvesupwardly and rearwardly from segment 245, and a straight upper segment249 which extends upwardly from arcuate segment 247. More particularly,each arcuate segment 247 has a lower front end which is secured to therear end of horizontal segment 245 at a lower connection or transition251. The bottom end of each straight segment 249 is secured to the topof each arcuate segment 247 at an arcuate upper connection or transition252 which curves in the opposite direction of segment 247. Each arcuatesegment 247 has a concavely curved front surface 253 and a convexlycurved back surface 255 which curve parallel to one another and liealong arcs of respective circles which are concentric about center X(FIG. 7) of inflated sphere 12 as viewed from the side. Front surface253 extends from the connection or transition 251 rearwardly andupwardly to a height equal to that of center X such that surface 253between the said height and transition 251 faces upwardly and forward.Surface 253 continues upwardly from the height of center X, curvingupwardly and forward therefrom to transition 252 whereby surface 253between transition 252 and the height of center X faces forward anddownwardly. As viewed from the rear (FIG. 9), each of support members235 appears straight and vertical whereby each lies along a respectiveplane parallel to plane P1. Left and right members 235A and 235B aresubstantially identical to one another or are mirror images of oneanother such that they are bilaterally symmetrical with respect to planeP1.

Each arm 234 in the exemplary embodiment is formed of a single tubewhich thus extends from a first or rear end 237 attached at a rigidconnection 239 to one of segments 247 below and rearward of transition252 to a second or forward end 241 attached at a rigid connection 243 tothe front end of segment 245 at or adjacent frame member 233. Rear end237 and connection 239 are rearward and higher than forward end 241 andconnection 243. FIG. 8 illustrates a line L2 extending through therespective centers of ends 237 and 239 or connections 239 and 243whereby line L2 and a horizontal plane such as floor F definetherebetween an obtuse angle K which illustrates in part that line L2angles upwardly and rearwardly. In the exemplary embodiment, angle K istypically about 135 degrees and more broadly in the range of about 120,125 or 130 degrees to about 140, 145 or 150 degrees although this mayvary. Left and right side-grip handles or grips 236A and 236B arerespectively secured around left and right arms 234A and 234B and aretypically formed of a resilient compressible material such as a foam,rubber, or elastomer. These grips of the handles may have built-in heartrate or pulse sensors. Arms 234 are described in greater detail furtherbelow.

Frame 214 further includes arcuate ball support 238 which supports ball12 and is described in greater detail further below. In the exemplaryembodiment, no glue, adhesive, or other fastening devices are used tosecure ball 12 to frame 214. Thus, ball 12 may be moved from the mountedposition shown in FIGS. 7-12 to a dismounted or removed positionanalogous to that shown in FIG. 2 separate from the frame by a simplemanual lifting force applied to the ball or seat. However, glue,adhesives, or other fasteners may be used to secure ball 12 to frame214. For instance, hooks, closed loops or links of a chain, or tethers,cords, or the like may extend from ball 12 to frame 214 in order tosecure the ball to the frame. A seat back 240 is secured to support 232as discussed above with regard to seat back 40.

Frame 214 includes a front section 242 and a rear section 244 which istypically removably connected to one another and in the exemplaryembodiment are selectively secured to one another by a securingmechanism 246 which serves as a length adjustment and detachmentmechanism. Mechanism 246 is configured to allow for the adjustment ofthe length of frame 214 and the length between the seat and pedals, asindicated at arrow A in FIG. 7. The portion of frame member 228 which iswithin front section 242 includes a straight horizontal rigid member inthe form of a tube 248 having a rear end 229 and a front end 231 rigidlysecured to front bar 24. Left and right rigid tubular members 250A and250B of support 230 are rigidly connected along their lower rear ends toopposed sides of tube 248 and also to the upper portion of front floorbar 24. Tubular members 250A and 250B include respective left and rightupper segments 256A and 256B. A series of longitudinally spaced holes 52(FIG. 11) are formed in the rear section of tube 248 as well as in thefront portion of frame member 233 such that the holes of each of thesemembers may be aligned with one another to receive therethrough asecuring peg 54 to secure the front and rear sections 242 and 244 in asecured position to one another at a selected length of frame 214. Inthe exemplary embodiment, the rear end 229 of frame member 248 isslidingly or telescopically received within the hollow interior chamber205 of tubular member 233, for instance at a rear position PR (FIG. 7).Although the use of holes 52 and peg 54 provides a simple securingmechanism for the length adjustment assembly, other suitable securingmechanisms known in the art may also be used.

As noted above, mechanism 246 may also serve as a detachment mechanismfor detaching front section 242 from rear section 244. Moreparticularly, peg 54 may be removed from holes 52 to an unsecuredposition to allow tube 248 to slide forward (Arrow A1 in FIG. 7)relative to the rear section in order to entirely remove tube 248 fromwithin interior chamber 205, as illustrated in dashed lines by end 229being located at forward position PF. Preferably, a forward foot 206 issecured to and extends downwardly from the bottom surface of framemember 233 adjacent front end 203, which in the exemplary embodiment isadjacent the forward lower ends 241 of arms 234 and adjacent connections243. Thus, when front section 242 is detached from rear section 244,foot 206 contacts floor F when seated thereon along with rear feet 25mounted on bar 26, thereby providing a three-point contact with floor F.Foot 206 is formed of the same type of material discussed above withregard to feet 25 in order to substantially prevent scratching floor Fwhen seated thereon. Rear section 244 and seat 12 are thus configured asa separate seat assembly which can be used simply as a seat or chair, oras a separate exercise device when detached from front section 242.

A rigid flywheel housing 258 is secured to frame 214 generally adjacentfront 16. In the exemplary embodiment, housing 258 is secured to tubes250. A rigid crank housing 259 is also secured to frame 214 generallyadjacent front 16. In the exemplary embodiment, housing 259 is securedto housing 258 and extends rearwardly therefrom to a connection withsupport bars 201 and 202 of the crank support assembly. Housing 258 and259 may be formed as a single unit or separate components. A set of leftand right pedals 60A and 60B is rotatably mounted via a rigid crank oraxle 62 about a horizontal axially extending axis B (FIGS. 7, 10) ofaxle 62. Crank 62 extends outwardly to the left and right from housing259 with respective pedal arms 64A and 64B extending transversely andtypically roughly perpendicularly to the crank 62. Left pedal 60A isrotatably mounted at the outer end of pedal arm 64A about a horizontalaxially extending axis C (FIG. 10) of a left pedal axle such that axis Cis parallel to and offset from axis B. Likewise, right pedal 60B isrotatably mounted at the end of pedal arm 64B about another horizontalaxis D of a right pedal axle such that axis D is parallel to axes B andC and offset therefrom. The pedal axles of pedals 60A and 60B thusoscillate during operation along respective circular paths concentricabout axis B while each pedal rotates about its respective pedal axle.Left and right crank-receiving holes 66A (FIGS. 1, 2) and 66B (FIGS. 5,6) are formed respectively through the left and right sides of housing259 for receiving therethrough respective portions of crank 62.

Rigid handle bars 268 are secured to the rear elevated free end of thecantilevered elevated support 230. Handle bars 268 include left andright segments with left and right front-grip handles 270A and 270Brespectively secured to the terminal ends thereof. Handles 270 typicallyinclude grips similar to the grips of handles 236, and thus are formedof like materials and may include heart rate or pulse sensors. It isnoted that handle bars 268 and/or handles 270 may be mounted in avariety of ways in order to allow them to move between various positionsas discussed above with regard to handle bars 68 and handles 70. Acombination display and control unit 272 is secured to upper bar 202 andextends upwardly therefrom. Display 272 includes the same features asdiscussed above with regard to unit 72. Display 272 is in electricalcommunication with built-in heart rate or pulse sensors in the grips orhandles 236 and 270. A resistance control 310 is also mounted on thecrank support assembly above housing 259.

With primary reference to FIGS. 7, 9A, 9B and 12, ball support 238 isnow described in greater detail. Support 238 includes a first or bottomplate 320 and a second or top plate 322 each of which is curved asviewed from the side. In the exemplary embodiment, bottom plate 320 isformed of a rigid material such as steel or another metal. However,plate 320 is sufficiently thin to allow for some flexing as describedfurther below. Bottom plate 320 is typically formed of a spring metal.Top plate 322 is in the exemplary embodiment formed of a material whichis less rigid than the material of bottom plate 320. In the exemplaryembodiment, top plate 322 is formed of a fairly rigid and resilientplastic which thus also allows for some flexibility and, like plate 320,the ability to return to its original position once the force causing itto flex has been removed. Bottom plate 320 has front and back axiallyelongated parallel ends or edges 324 and 326. Back edge 326 in theexemplary embodiment is rearward of and higher than front edge 324.Plate 320 also has left and right longitudinally elongated paralleledges 328 and 330 extending from the front edge 324 to back edge 326 andintersecting the front and back edges at respective right angledcorners. Edges 324, 326, 328 and 330 thus form an outer perimeter ofplate 320 as viewed from below (FIG. 12). Bottom plate 320 has adownwardly facing bottom surface 332 and an upwardly facing top surface334 each of which extends from front edge 324 to back edge 326 and fromleft edge 328 to right edge 330. As shown in FIG. 9A, bottom plate 320and thus its lower and upper surfaces 332 and 334 are straight andhorizontal as viewed in a cross section looking forward. As viewed fromthe side (FIGS. 7, 8, 9B), bottom surface 332 is convexly curved fromfront edge 324 to back edge 326 and forms an arc of a circle which isconcentric about center X of sphere 12. As viewed from the side, topsurface 334 is concavely curved from front edge 324 to back edge 326 andlies along an arc of a slightly smaller diameter circle which isconcentric about center X. The radius of curvature of bottom surface 332is substantially the same as that of front surface 253 of each supportmember 235.

Bottom plate 320 is rigidly secured to support members 235 with bottomsurface 332 in contact with front surface 253 from back edge 326 for asubstantial distance to about the transition 251 between segments 245and 247. Bottom surface 332 is thus in a mating engagement with frontsurface 253 and in continuous contact from back edge 326 toward frontedge 324 along a distance which is in the exemplary embodiment over halfof the longitudinal distance along bottom surface 332 and in theexemplary embodiment about ⅔ of that distance. Bottom surface 332 fromfront edge 324 to adjacent transition 251 is spaced upwardly of and thusout of contact with the horizontal upper surfaces of segments 245 andmember 233. The front section of bottom plate 320 is thus cantileveredupwardly and forward from adjacent transition 251 to front end 324,which serves as a terminal free end of plate 320.

Top plate 322 has front and back ends or edges 336 and 338 and left andright edges 340 and 342 which together form an outer perimeter of topplate 322 which extends outwardly beyond the outer perimeter of plate320 in all directions as viewed from below. Front edge 336 is forward ofand higher than front edge 324 of bottom plate 320. Rear edge 338 isrearward of and higher than rear edge 326 of bottom plate 320. Left edge340 extends outwardly to the left beyond left edge 328, and right edge350 likewise extends outwardly to the right beyond right edge 330. Topplate 322 has bottom and top surfaces 344 and 346 which extend fromfront edge 336 to back edge 338 and from left edge 340 to right edge342. As shown in FIG. 9A, top plate 322 and thus its lower and uppersurfaces 344 and 346 are straight and horizontal as viewed in a crosssection looking forward. As viewed from the side, bottom surface 344 isconvexly curved from front edge 336 to back edge 338 and forms an arc ofa circle which is concentric about center X and has a radius ofcurvature which is substantially the same as that of top surface 334 ofbottom plate 320. As viewed from the side, top surface 346 is concavelycurved from front edge 336 to back edge 338 and forms or lies along anarc of a circle which is also concentric about center X and has a radiusof curvature R (FIG. 7) which is substantially the same as that of outersurface 82 of sphere 12 in the inflated resting state of sphere 12.Thus, when seat 12 is inflated and in its resting state, outer surface82 contacts top surface 346 in a substantially continuous manner fromfront edge 336 to back edge 338 when seat 12 is seated atop support 238.Top plate 322 is rigidly secured to bottom plate 320 by rivets or anyother suitable securing mechanism so that top surface 334 of bottomplate 320 is in its entirety or almost in its entirety in contact withbottom surface 344 of top plate 322. Thus, top surface 344 from frontedge 324 to back edge 326 is in substantially continuous contact withbottom surface 344. In addition, top surface 344 is in substantiallycontinuous contact from left edge 328 to right edge 330 with bottomsurface 344.

As best illustrated in FIG. 12, the outer perimeter of top plate 322 iscurved in a manner so that the outer perimeter has no sharp corners.Thus, front edge 336 faces forward and upwardly and is convexly curvedwhile rear edge 338 faces primarily upwardly and is also convexlycurved. Top plate 322 along the left side has three lobes which extendoutwardly to the left beyond left edge 328 of bottom plate 320 and alsobeyond a pair of respective recesses formed between the lobes. Likewise,plate 322 along the right side has three longitudinally spaced lobeswhich extend outwardly to the right beyond right edge 330 of bottomplate 320 and also beyond a pair of recesses defined respectivelybetween the lobes. The front lobes along the left and right sides ofplate 322 each have front convexly curves outer surfaces 348 which facerespectively generally to the left and right. Similarly, theintermediate lobes along the left and right of plate 322 haveintermediate convexly curved outer surfaces 350 which respectively facegenerally to the left and right. In addition, the left and right rearlobes of plate 322 have back convexly curved surfaces 352 whichrespectively face generally to the left and right. A first or frontconcavely curved surface 354 extends between the respective front andintermediate lobes and communicates smoothly with the respective frontand intermediate convexly curves surfaces 348 and 350. Similarly, asecond or rear concavely curved surface 356 extends between therespective intermediate and rear lobes and communicates smoothly via agenerally straight edge section with the respective intermediate andback convexly curved surfaces 350 and 352.

Referring to FIGS. 7-12, arcuate left and right arms 234A and 234B ofthe frame include respective left and right rear segments 274A and 274Bwhich extend respectively axially outwardly, upwardly and forward fromthe respective member 235 of support 232, respective intermediatesegments 276A and 276B which extend respectively forward from rearsegments 274A and 274B, and front segments 278A and 278B which extendrespectively downwardly from the front of intermediate segments 276A and276B. Front segments 278A and 278B adjacent their lower ends extendaxially inwardly toward their rigid connections 243 with segments 245and frame member 233. More particularly, left and right rear segments274A and 274B extend axially outwardly from upright 232 and curveforward and slightly upwardly therefrom to transition respectively intoleft and right intermediate segments 276A and 276B, which curve forward,downwardly and inwardly to transition into left and right front segments278A and 278B. As viewed from above (FIG. 11), rear segments 274A and274B curve so that their inner surfaces 285 curve concavely and facegenerally forward and axially inward toward one another and plane P1while their outer surfaces 287 curve convexly and face generallyrearwardly and axially outward away from one another and plane P1. Asviewed from above (FIG. 11) or from the side (FIGS. 7-8) intermediatesegments 276 curve so that their inner surfaces 288 curve concavely andface generally axially inward toward one another and plane P1 whiletheir outer surfaces 290 curve convexly and face generally axiallyoutward away from one another and plane P1. As viewed from the side, thebottom downwardly facing surfaces 289 of rear segments 274 andintermediate segments 276 curve concavely, while their top upwardlyfacing surfaces 291 curve convexly. As viewed from the side, therearwardly facing back surfaces 293 of front segments 278A and 278Bcurve concavely while their front forward facing surfaces 295 curveconvexly. The lower ends of front segments 278A and 278B curverearwardly to their respective connections 243 with segments 245 andframe member 233. As viewed from behind (FIG. 9) or from above (FIG.11), left and right arms 234A and 234B together form a substantiallyheart-shaped configuration.

In the exemplary embodiment, each arm 234 curves from adjacent its rearend 237 to its front end 241 along an arc of a circle. In addition, asshown in FIG. 9C, left and right arms 234A and 234B lie in theirentirety along respective planes P2 and P3 which intersect at a line L3which lies within plane P1 and is parallel to line L2, (FIG. 8). Line L3and a horizontal plane such as floor F define therebetween angle K,which thus is the same as the angle formed between line L2 and thehorizontal plane. As viewed along line L3 (FIG. 9C), planes P2 and P3define therebetween an angle Q which in the exemplary embodiment isabout 90 degrees and which typically falls within the range of about 70,75, 80 or 85 degrees to about 95, 100, 105 or 110 degrees. Plane P1 andP2 as viewed along line L3 define therebetween an angle S as do planesP1 and P3. Angle S is thus half the value of angle Q.

Frame 214 adjacent rear end 18 defines a ball receiving space 275 havinga top entrance opening 277, a front entrance opening 279, a left rearentrance opening 281 and a right rear entrance opening 283.Ball-receiving or seat-receiving space 275 is generally defined betweenarms 234A and 234B, forward of upright 232 and above ball support 238.In the exemplary embodiment, top surface 346 of top plate 322 definesthe bottom of space 275, the front surface 253 of segments 247 ofmembers 235 define the back of space 275, and portions of intermediatesegments 276 and/or front segments 278 of arms 234 typically define theleft and right sides of space 275. Top entrance opening 277 is definedbetween intermediate segments 276A and 276B while front entrance opening279 is defined between front segments 278A and 278B. Left rear entranceopening 281 is defined generally between left arm 234A, left edge 340 oftop plate 322, and the upper portion of segment 247 of left supportmember 253A extending upwardly from back edge 338 of top plate 322 toconnection 239. Similarly, right rear entrance opening 283 is definedgenerally between right arm 234B, right edge 342 of top plate 322, andthe upper portion of segment 247 of right support member 253B extendingupwardly from back edge 338 of top plate 322 to connection 239. In theexemplary embodiment, each of the entrance openings 277, 279, 281, and283 is completely or substantially free of any components extendingbetween the various structures which define said entrance openings. Inthe exemplary embodiment, machine 200 is free of or substantially freeof components extending into space 275 other than inflated seat 12.

When inflated seat 12 is mounted at rest on frame 214, the bottom ofouter surface 82 is seated on top surface 346 of plate 322, as areportions of outer surface 82 extending forward and upward therefrom tofront edge 336 and extending rearward and upward therefrom to back edge338. A rearward portion of outer surface 82 above back edge 338 isadjacent and spaced forward out of contact with front surface 253 ofseat support 232. Left and right forward lower portions of outer surface82 in the forward half and lower half of the spherical seat 12 areclosely adjacent or abut the lower portions of front segments 278A and278B at contact points 358 (FIGS. 7, 8, 10). In addition, left and rightrearward upper portions of outer surface 82 in the rearward half andupper half of seat 12 are closely adjacent or abut segments 274A and274B respectively at contact points 360 (FIGS. 7-9). Typically,intermediate segments 276A and 276B are spaced outwardly from seat 12and are thus not in contact with outer surface 82 of seat 12 at rest orwhen compressed when a user is seated thereon. Also typically, the abovenoted places of contact or interface between outer surface 82 and thevarious surfaces of frame 214 are the only places of contact between theball and frame when the inflated ball is at rest whereby the remainderof outer surface 82 is out of contact with frame 214. The portions ofthe frame which extend upwardly and contact the outer surface of seat 12substantially prevent it from rolling atop plate 238. Seat 12 is alsosubstantially non-rotatably mounted within space 275 due to frictionalengagement (or securing devices if used) between seat 12 and frame 214.

When sphere 12 is inflated and in its resting state, frame 214 isconfigured to receive seat 12 within receiving space 275 through topentrance opening 277 and typically through a portion of front entranceopening 279, which together form an entrance opening which extendsgenerally upwardly and forward along intermediate segments 276 and frontsegments 278. Seat 12 is thus inserted downwardly and rearwardly throughentrance openings 277 and 279 until it is seated atop ball support 238.This insertion of sphere 12 into space 275 may or may not involvecompression as discussed above regarding bike 10.

Generally, left and right rear entrance openings 281 and 283 areconfigured so that at least one dimension of the respective entranceopening is sufficiently less than the diameter of the inflated ball inorder to prevent it from moving through the respective entrance openingduring use of machine 200. When inflated ball seat 12 is positioned at astate of rest in receiving space 275, side grip handles 236 and most ofsegments 276 are at a height which is a little lower than the top ofball 12 although they may be slightly higher or at the same height.Handles 236 and intermediate segments 276 are typically substantiallyabove the height of the midway point between the top and bottom of theball, (the center X of the ball) and typically at least ¾ of the heightof the ball. The uppermost points 301 of each arm 234 are likewise at aheight which is about the same as that described above with regard tohandles 236. In addition, the uppermost points of 301 are in theexemplary embodiment positioned along the rear half of sphere 12. Inaddition, uppermost points 301 are generally adjacent and axiallyoutward of the bottom of seat back 240. The forward most point 303 ofeach front segment 278 is typically spaced longitudinally forward fromthe seat support or back end 18 about the same distance as the frontmost portion of ball 12.

Referring now to FIGS. 7, 8 and 10-12, housing 258 includes left andright vertical panels 314A and 314B. Housing 258 further includes aperimeter wall 316 which is connected to the respective outer perimetersof vertical panels 314 whereby panels 314 and perimeter wall 316 definetherewithin an interior chamber 317 of housing 258. A generally flat andvertically oriented flywheel 318 is disposed within interior chamber 317and rotatable about axis J, which is parallel to axes B, C and D andoffset forward thereof. A driven sprocket or pulley 313 secured to oneside thereof with its outer perimeter concentric about axis J. Aresistance mechanism 120 is provided within the interior chamber ofhousing 259 and is controlled by resistance control 310 in order toallow the user to control the amount of resistance on flywheel 318 andthus to the pedaling motion of the user. The various resistancemechanisms described with regard to bike 10 may be used. A drivesprocket or pulley 311 is mounted within interior chamber of housing 259with an outer perimeter which is concentric about and rotates about axisB. A drive chain or belt 312 is looped around the outer perimeters ofpulleys 311 and 313 so that rotation of drive pulley 311 drives therotation of driven pulley 313 and fly wheel 318 via belt 312. Holes 66Aand 66B are formed respectively in left and right vertical panels 208Aand 208B such that crank 62 extends axially outwardly from drive pulley311 therethrough. Thus, the user places his feet on pedals 60 to forcethe pedals to rotate about axis B and the fly wheel 318 to rotate aboutaxis J via the above described drive chain.

Generally, bike 200 operates in the same manner as bike 10 although bike200 in the exemplary embodiment does not include the air compressor orsensor which was used with bike 10 to adjust the degree of inflation ofball 12. Thus, the user typically rests his back against seat back 240while seated on inflatable seat 12 and pedaling the stationary bike. Theuser may hold handles 270 or 236 or may choose not to hold on to anyhandles, as described with regard to bike 10. The manner in which aperson will use bike 200 is essentially the same as discussed withregard to bike 10 and thus is not described in any greater detail here.

As noted with regard to bike 10, the movement of the inflated seat 12from its resting state to its compressed state (analogous to FIG. 6 andshown in dashed lines in FIGS. 9A and 9B) in response to the downwardforce of the user seated thereon increases the surface area of contactbetween outer surface 82 and frame 214. More particularly, FIG. 9Aillustrates in solid lines that outer surface 82 at the bottom of thesphere 12 contacts only a portion of top surface 346 of top plate 322generally midway between edges 340 and 342 in the resting state whereasthe surface area of contact between outer surface 82 and top surface 346of plate 322 in the compressed position (dashed lines), a substantiallygreater portion and typically the entire top surface 346 is in contactwith outer surface 82. The movement of bladder wall 80 adjacent left andright edges 340 and 342 of top plate 322 is shown at Arrows M. Inaddition, FIG. 9B illustrates that outer surface 82 above back edge 338of top plate 322 moves from a position shown in solid lines out ofcontact with front surfaces 253 of segments 247 to a compressed positionshown in dashed lines in contact with surfaces 253. In addition,movement from the resting state to the compressed state either bringsouter surface 82 into contact with points of contact 358 (FIG. 10) and360 (FIG. 9) or simply increases the amount of contact between outersurface 82 and arms 234 around said points of contact.

FIG. 9B also illustrates the flexing movement of ball support 238 atarrows N and O. More particularly, when the user sits atop ball 12 andthus causes ball 12 to move from its resting state to its compressedstate, the downward and/or forward force on ball 12 is transferred inpart to top plate 322 and bottom plate 320 adjacent the free front ends326 and 324 thereof. This downward force causes plates 320 and 322 toflex downwardly in a pivoting manner about a portion of plates 320 and322 adjacent transition 251 from the resting state or position shown insolid lines to the compressed or downwardly flexed position shown indashed lines. Once the user gets off of ball 12 and thus removes thedownward force, the spring biased characteristic of bottom plate 320 andresilient nature of top plate 322 cause the front ends of plates 320 and322 to flex pivotally back upward from the compressed or flexed state tothe resting state. This flexing movement is illustrated by arrow N inFIG. 9B. In addition, the downward pressure on the top of seat 12applies a radially outward force along bladder wall 80 which istransferred in part rearwardly against top plate 322 adjacent back edge338 such that the upper rear portion of top plate 322 flexes pivotallyadjacent back edge 322 of bottom plate 320 from a position shown insolid lines spaced forward of surfaces 253 to a flexed position shown indashed lines which is closer to or in contact with surfaces 253.

It will be evident to one skilled in the art that various alterationsmay be made which are within the scope of the present invention. Forinstance, the shape of the inflatable seat may vary beyond thoseillustrated in the figures. In addition, the mounting structures used tosecure the inflatable seat to the frame may vary beyond those shown inthe figures. While the seat of the invention has been described above asbeing inflated with air or another gas, it may also be a liquid filledseat which also allows for a substantial amount of flexibility of thebladder during operation. A gas filled bladder is typically preferredinasmuch as it reduces the amount of weight while also minimizing theresistance to the flexible movement of the bladder compared to a liquidfilled bladder. In addition, other seats may be configured to providethe substantial amount of movement required to provide a workout of theuser's core muscles during operation. For example, a gel seat or anotherseat formed of certain types of semi-solid materials may be configuredto provide the suitable type of movement to provide this core workout.Any of the inflatable seats may be used with or without a valve forcontrolling the inflation. An alternate pneumatic system may be providedwhich is not powered by the user, such as an electrically poweredcompressor which may or may not include a tank of compressed air. Inaddition, the cardiovascular and core workout provided by the bike isachieved whether or not the pneumatic system for adjusting the height ofthe seating surface is used. While the sensor described herein uses alaser beam for determining the height of the seating surface of theinflated seat, other known distance sensors may be used. An alternateheight adjustment for the seat may also be used, such as a standardtelescoping pole with a securing mechanism to secure the pole, mountingstructure of the seat and inflated bladder at a desired height. Inaddition, the pedaling mechanism may be altered to one other than theillustrated pedaling concept in which the axles of pedals 60 move abouta circular path around axis B while pedals 60 simultaneously pivot abouttheir respective pedal axles. For instance, the bike may be configuredwith pedals that move along an elliptical path with or without rotationof the individual pedals about respective axles. In addition, the bikemay be configured such that the pedals will move back and forth along astrictly linear path, for instance, more like a “stepper” machine. Eachof these options provides an oscillating movement of the user's feet andpedals during operation. In addition, the set of pedals in the exemplaryembodiment is secured to fly wheel 118. Furthermore, while thestationary bike of the present invention is shown as a recumbent typebike, it is also contemplated that the present invention may beconfigured more as an upright stationary bike. The bike may also beconfigured with various structures convenient to the user such as a keyholder, a cup holder or bottle holder, a towel rack or other type ofholder for towels, and so forth. Other modifications within the scope ofthe present invention will be evident to one skilled in the art.

In the foregoing description, certain terms have been used for brevity,clearness, and understanding. No unnecessary limitations are to beimplied therefrom beyond the requirement of the prior art because suchterms are used for descriptive purposes and are intended to be broadlyconstrued.

Moreover, the description and illustration of the invention is anexample and the invention is not limited to the exact details shown ordescribed.

1. A method of simultaneously undertaking a cardiovascular workout and acore workout comprising: providing an exercise machine having a framewith a set of pedals movably mounted thereon; a seat-receiving spacedefined by the frame, an inflated seat retained within theseat-receiving space; wherein the seat-receiving space includes a leftarm and a right arm that extend respectively to the left and right ofthe inflatable seat; and a back rest positioned adjacent and rearward ofthe seat-receiving space; sitting on an outer surface of the inflatedseat; engaging the set of pedals and pedaling; moving the inflatableseat within the seat-receiving space while pedaling; and balancing onthe inflatable seat while the inflatable seat is moving and whilepedaling.
 2. The method as defined in claim 1, further comprising:preventing rotation of the inflatable seat within the seat-receivingspace through frictional engagement between the seat and the frame. 3.The method as defined in claim 1, further comprising compressing anddecompressing the inflatable seat while balancing on the inflatable seatand pedaling.
 4. The method as defined in claim 1, wherein the left andthe right arm flare outwardly away from each other moving in a directionaway from the back rest and toward the set of pedals.
 5. The method asdefined in claim 1, further comprising: gripping a handle on an end ofeach of the left arm and the right arm while pedaling; and measuring aheart rate or a pulse while gripping the handles.
 6. The method asdefined in claim 1, further comprising: restraining the inflatable seatin the seat-receiving space, wherein the left and right arms of theseat-receiving space include rear segments adjacent the back rest,intermediate segments that are connected to and extend forwardly fromthe rear segments, and front segments respectively connected to andextending downwardly from the intermediate segments.
 7. The method asdefined in claim 6, wherein the restraining of the inflatable seat inthe portion of the frame is accomplished without glue, adhesive, orother fastening devices.
 8. The method as defined in claim 7, furthercomprising moving the inflatable seat from a mounted position withinseat-receiving space to a dismounted position wherein the inflatableseat is separate from the seat-receiving space by applying a manuallifting force to the inflatable seat.
 9. The method as defined in claim1, further comprising: positioning a display and control unit on a frontsection of the frame; and operating functions on the exercise machine bycontacting controls on the display and control unit.
 10. The method asdefined in claim 9, manually operating the display and control unitthrough user contact with one or more of buttons, heat sensitive padsand pressure sensitive pads provided on the display and control unit.11. The method as defined in claim 9, further comprising: viewing avideo screen on the display and control unit while seated on theinflatable seat and while pedaling the set of pedals.
 12. The method asdefined in claim 9, further comprising: adjusting a longitudinalposition of the front section of the frame relative to a user sitting onthe inflatable seat by telescoping the front section of the framerelative to a rear section of the frame that includes the inflatableseat.
 13. The method as defined in claim 1, further comprising: restingagainst a back rest that is positioned rearward of the inflatable seatwhile balancing on the inflatable seat and pedaling.
 14. The method asdefined in claim 1, further comprising: selectively holding onto one ofthe left arm and the right arm adjacent the inflatable seat, and leftand right grip handles provided on a front section of the frame whilebalancing on the inflatable seat and pedaling.
 15. The method accordingto claim 1, further comprising: fabricating the inflatable seat to haveone of a bladder and a wall; and wherein the fabricating includesselecting a material for the one of the bladder and the wall that isimpermeable to air or a gas used to inflate the inflatable seat.
 16. Themethod according to claim 1, further comprising: adjusting a level ofinflation of the inflatable seat based on a weight of a user sitting onthe inflatable seat.
 17. The method according to claim 16, wherein theadjusting of the level of inflation is preceded by measuring a verticaldistance between a sensor at a bottom of the inflatable seat and areference point proximate a top of the inflatable seat.
 18. The methodaccording to claim 17, wherein the measuring includes: emitting a laserbeam from the sensor to the reference point; reflecting the laser beamback to the sensor from the reference point; and sending a signal to amicroprocessor of a control unit upon receipt of the reflected laserbeam.
 19. The method according to claim 18, further comprising:partially inflating or partially deflating the inflatable seat based onreceipt of the signal at the microprocessor.
 20. The method according toclaim 1, further comprising: performing one or more of a cardiovascularworkout and a core workout on the exercise machine.